Gas and other fluid pressure controlling apparatus



(NoMode1.) 2Sheets-Sheet 1. vH. W. 8v A. P. COLE.

GAS AND OTHER FLUID PRESSURE GONTROLLING APPARATUS.

No. 376,636. l Patented l-xix I I fil/v 25mg/23x63 Y @QM WM/@w E7 fg/M@ MM f5@ ATTO RNEYS (No Model.) 2 Sheets-Sheet A2.

- W. 8v A. E. COLE. GAS AND OTHER PLUIE PRESSURE CONT-ROLLING APPARATUS. No. 376,636.

Patentedv Jan. 1'7, 1888l N. Pnzns, Phone-magnum wnsmngmn. u:c.

'I UNITED STATES PATENT vOEEICE.

HENRY WILLIAM COLE AND ALBERT FREDERICK COLE, OF STOURPORT, COUNTY OF WORCESTER, ENGLAND.

GAS AND OTHER FLUID PRESSUREl CONTROLLING APPARATUS.

SPECIFICATION forming part oiLetters Patent No. 376,636, dated January 17, 1888. Application filed March 529, 1887. Serial No. 232.851. (No model.) Patented in England November 525, 1886, No. 15,404.

To @ZZ whom t may concern,

Be it known that we, HENRY WILLIAM CoLE and ALBERT FREDERICK COLE, subjects of the Queen of Great Britain, residing at Stourport,

in the county of Worcester, England, manu The instrument consists of a Vchamber with inlet and outlet openings for the gas, and

within this chamber is pivoteda lever, which carries at one end avalve or equivalent which controls the outlet, and at the other end has a balancing device subject to the pressure of the gas on both sides. The valve may preferably be in form of a cup dipping into a mercury seal, and the balancing device is preferably a flexible diaphragm loaded as required and connected'with the leveraforesaid. A piston working in an open-ended cylinder or a second mereury-cup would give the same result; but a leather diaphragm isv found to give satisfaction. Upon the leveris a projection having inclined faces adapted to be moved or con trolled by two arms extending from an aXis crossing the direction of the lever. The projection forms, with the pivoted lever, a bellcrank lever, and the axis carrying the arms revolves so that the arms traverse the angle between the projection and the lever.

The action of this part of the apparatus is as follows: The chamber above the valve and diaphragm is put under pressure as soon as the tap on the main is opened; but the gas cannot pass, because one of the arms is pressing upon the lever and holding the cup down in the mercury seal. By means which will be presently explained the action ofIopening the tap in the main has set the spindle which carries the arms revolving,preferably with an intermittent motion, so that as the arm which to give time for any leak to manifest itself or for the pressure to equalize on both sides of the apparatus. If this equalization takes place, there can be no leak; but thesecond arm,whieh moves on again, engages with the lever and forces the cup again into the mercury, where it holds it for a longer orv shorter time, to which it is set according to the length of piping which has to be tested, and then continuing leaves the lever entirely free. If at this period there be no escape, the diaphragm end, being slightly the heavier, although the shorter, overpowers the cup end and tips it up, the lever allowing a clear way for the passage of the gas when it is wanted. If, however, there be a leakage, the cup, being on the longer end of the lever, is held in the mercury by the pressure of the gas and closes the passage, and so remains until the leak is stopped; or, if a tap has been left open by mistake until it has been closed, the tap is now again turned oft` at the main andthe apparatus set going asecond time, and, the equilibrium being restored, the valve remains open and the passage way is clear. This apparatus is therefore of great utility where the gas is turned off every night, as it' any tap has not been turned off it must be shut before any gas can be obtained for use.

Various means may be employed for giving motionto the spindle which carries the arms above mentioned; but the following is found to Work well:

A weighted lever pivoted at one end is controlled in its descent by some regulating device-such as is commonly used for the levers of water-closets-an air or oil cylinder with a regulating tap or hole and piston being preferred. This lever is so connected with the tap on the gas-main that when the tapis closed the lever is raised and is held up by a detent, which is only released when vthe tap has been turned full on. Supposing this to have been done, the lever descends slowly, and carrying with it a section or quadrant which has pins or teeth, which engage in turn with arms or teeth upon the outer end of the spindle already mentioned. rlhcse are preferably arranged at intervals, so as to give the intermittent motion, which, as already explained, is preferred; but a toothed segmentand toothed wheel could be used, or other equivalent means.

rlhe cylinder which controls the descent of the lever we prefer to pivot at its closed end, so that it may oscillate, as required, and to keep it always in the proper line we connect itwith a slotted arm, through the slotof which passes a pin fixed in the weighted lever. f The result is that this arm and the piston-rod are always practically parallel, and the cylinder is always in its proper position.

This apparatus may be employed for other llnids besides gas-comprcsscd air, for instance; but we have described it as applied to gas. Although we have described our apparatus as heilig coupled with the tap in the main, the latter may be dispensed with in some cases and the apparatus itself substituted therefor.

In the accompanying drawings, Figure l represents a front elevation, partly in section, as indicated by the line .r ,cf in Fig. 2. Fig. 2 is a side elevation, and Figs. and iv are details of the chamber containing the controlling apparatus.

rlhis chamber is formed in two parts, A and A', lutcd and screwed or otherwise fastened together so as to be perfectly gas-tight. In one part of the chamber is formed an annular groove, a, to contain mercury, and concentric with this groove is au opening, l5, for the outlet of the gas. This opening may be closed by means of au inverted cup, af, the rim of which dips into the mercury contained in the groove a. rllhe cup a is attached to the longer arm of a lever, C, which is pivoted at c, the shorter arm of thesaid lever being attached to a collapsible diaphragm ot' leather or other flexible material, D. Dy means of passages D communication is established between the outlet B and the under side of the diaphragm. For convenience of manufacture, the bottom A2 of the chamber is separately constructed and attached by screws to the upper parts. By means of a counterbalaneeweight, C', adjustable on the rod CF, which may be either fixed to orform partei' the lever C, the equilibrium ot' the said lever, when the latter is uninfluenced by other agency, is disturbed, the diaphragm end being slightly heavier than the other, and therefore tending to make the parts assume the posit-ion shown in Fig. 3.

Attached to or forming part ot' the lever C is a ca1n-faced projection, C, and projecting transversely across the lever C is aspindle, E, which passes through a gland or stuftingbox, E', formed on the part A of the chamber. From a boss on the spindle E and at right angles to each other project two arms, c c', arranged to act on the lever Gand projection C to effect the opening and closing ofthe valvea.

The remainder of the apparatus shown in the drawings hereto annexed is concerned in operating the spindle E; but as the regulator would act equally well if the spindle were turned by hand we will nowdcscribe the working thereof. The condition of the parts previous tocommencing operations is that shown in Fig. 1, in which the valve a is immersed in the mercury in the groove a and the diaphragm D distcnded, this position being maintained by means of the arm c on the spindle E, which bears on the lever G. ll' gas be now turned on at the main, it will enter through the inletpipe B' into the chamber A, from which there is at presentno outlet. The spindle E must new be turned slowly round in the direction of the arrow, and the first motion thereof will canse the arm c to leave the lever C, and almost simultaneously the arm e will commence to act on the inclined face of the projection C, and, forcing the same back, will continue to raise the valve a from the mercury seal e until a free passage for gas through the outlet B is provided. \Vhen the arm c has reached the apex or summitof the incline on the projection C, the rotation of the spindle is suspended for a while until all the branch pipes on the outlet side have had time to become full of under the same pressure as that on thcinletside or main, or until the pressureson each side of the regulator are in equilibrium. The rotation of the spindle is then continued until the arm c'eomes into contact with the lever C and commences to close the valve e', which it does completely when the pin has arrived at the vertical position underneath the spindle, acting precisely as the arm e did previous to the commencement ofthe operation.

The rotation of the spindle E is at this stage again suspended and the valve allowed to remain closed for a short time, so that should any leak exist on the outlet side of the rcgulator, either through a flaw in the pipes or a tap being turned on, the gas o n the outlet side may have time to escape and the pressure in thepipesbecomeappreciablydinlnished. lhe spindle E is then turned until the arms c and c are clear of the lever C and have left the Same free to open the valve. As previously stated, the weight of the parts on each side of the fulcrum is so adjusted that thediajihragm end of the lever C is heaviest and will, when free to do so, overcome the weight on the valve side and raise the valve e from the mercury cup or trough a. lt follows from this that if, when the spindle E has been turned round so as to remove the arms c and c' out of possible Contact with the lever C, no opening for escape should exist,the pressure of gas on each side of the valvea and diaphragm D will be equal and will not affect the balance of the lever C, and therefore the preponderance of weight on the IOO IOS

IIO

diaphragm side of the lever will assert itself, the diaphragm will sink, and the valve a. will be raised, so as to afford a passage for the gas when necessary. Supposing, however, that a leak should exist, thegas during the time that the valve .af has been closed will have escaped to such an extent that the pressure in the branch pipes will be considerably less than in the-upper portion of the regulator. Under such circumstances the valve a' will remain closed, as the pressure on the upper side thereof multiplied by the difference in length ofthe two arms of the lever C willamore than counterbalance the excess in weight of the diaphragm end ofthe lever. The fact ofthe valve remaining closed may therefore be regarded as evidence of a leak existing, and until such has been stopped and the equilibrium between the main and the branch pipes restored by repeating the operation ot' opening the valve by means of the arms on the spindle E the valve will continue to close when released.

In the foregoing description the diaphragm has been described as attached to the end ,of the lever C and assisting to counterbalance the weight of the Valve a'. Instead of this the diaphragm may be attached to the end of a separatelever, O, (see Fig. 4,) mounted loosely on the same pivot, c, the shorter end of the lever being provided with a cam or inclined tail-piece, o', capable ot' being acted upon by the arms e and e', or `others similarly placed.`

In this case Vthe valve is counterbalanced entirely by the weight C. As the spindle E re-y volves, the arms e and e', acting on the inclined tail-piece o', will raise the diaphragm at the same time as they close the valve. The space underneath the diaphragm thus becomes lled` with gas, and when the .arms e and e are removed from the spindle C and the cam O the diaphragm immediately falls and compresses the gas in the passages D and B. This displacement of gas from beneath the diaphragm compensates for the slight vacuum which would be produced by the raising Vof the valve a and helps to start the same in its opening motion.

As will be readily seen from the foregoing description, the motion of the spindle E is intermittent, the pauses varying according to the length of` time requisite for filling the branch pipes and for allowing a leak to manifest itself by an appreciable diminution of pressure. In order to render this motion automatic, the following mechanism may be employed: Uponaboss,F, mounted on the spindle Eoutside the regulating-chamber A, are fixed a series of Vradial pins or pegs, F. These pins gear with a second series of pins, G, fixed perpendicularly to an arm, G', forming a segment ot' a circle, of which the stud II is the center. On this stud is mounted a lever, J, to which the arm G' is fixed. To a stud, J', on the lever .lis pivoted a rod, K, carrying at its lower enda piston, K', which fits into an air-cylinder, K2, at the bottom of which is a small pet-valve, K3.

The function ofthe lever J is to impart rotation to the spindle E through the mediation of the pins F and G. Vhen the apparatus is set,77 the lever is elevated, as shown in Fig. 1, being retained in position by means of a catch-lever, L, which is pivoted to the lever J and rests on one of the branch arms A3, which snpportthe rcgulati11g-chamber. An arm, M, having a projection, D is pivoted on the stud II and connected, by means of a rod, M2, with a crank, N, on the spindle of the valve N in the main or supply pipe. Vhen the gas is turned on, the arm M is thrown forward, and the projection M strikes the upper end of the catch-lever L and disengages the same, thereby leaving the lever .I free to drop. The rate at which the lever falls is governed by the air-cylinder K2, while the periods of act-ion and inaction on the spindle E are governed by the distance apart-of the pins G on the segment G.

The mechanism above described for imparting the requisite slow and intermittent motion to the spindle E is merely an illustration of the manner in which the invention may be carried into practical effect. It is obvious that this part ofthe apparatus admits of considerable modification, or automatic mechanism may be entirely dispensed with.

Ve claim- 1. The herein-described method of detecting leakage of gas or otheriiuid under pressure in the pipes conducting same, which consists in admitting such fluid to a suitable reservoir, opening communication between said reservoir andegresspipes leading therefrom, cutting off the flow of said iluid to said egresspipes, and, after an interval of time, utilizing the relation of pressure for automatically determining the presence or absence of leakage, for the purpose set forth. v

2. The combination, with the gas-chamber having openings for the ingress and egress of the fluid, of a compensating-lever carrying a valve on one end and a weighted balancing device, such as described, upon the other cX- tremity, a mercury cup or seal for said valve, and means for intermediately and gradually operating the said lever according to the amount of gas or iluid admitted to said chamber from the main or other source, as described.

3. The combination, 4with the duid-chamber hav-ing openings for the ingress and egress of the fluid, of theu lever carrying a valve and diaphragm operated by the varying pressure in the chamber andservice-pipes, and a spindie carrying a suitable arm or arms for imparting the requisite intermittent motion to the said lever, substantially as specified.

4: The combination, with the fluidehamber provided with ingress and egress openings, of the valve-lever located entirely within said chamber and having a valve and flexible diaphragm, and a balance arm 'and movable weight for regulating the operation of the valve to ,compensate for the variable pressure of the IIS,A

Huid in the chamber and Service-pipes, substantially as specified.

5. The combination, with a valve-lever havin g,` the Cain projection ab its fuleruln-point, of the spindle provided with radial arms which engage and operate upon said projection, and means vl'or intermittently rotating said spindle, as specified.

In testimony whereof we have hereunto set our hands in the presence of two subscribing ro witnesses.

HENRY XVILLTAM COLE. ALBERT FREDERICK COLE. Vihnesses:

W. lfnnsnr, C no. C rmnnrr. 

